Selection of the 3′-splice site in group I introns

A model for selection of 3′-splice sites in splicing of RNA precursors containing group I introns is presented. The key feature of this model is a newly identified tertiary interaction between the catalytic core of the intron and the 3′-splice site. This tertiary pairing would bring the 3′-splice site into the core of the intron, which is known to contain RNA sequences and structures essential for catalyzing the splicing reactions. The proposed tertiary interaction can coexist with P10, a pairing between 3′-exon sequences and the ‘internal guide sequence’ near the 5′-end of the intron. The model predicts that three RNA-RNA interactions are important in selection of 3′-splice sites: (i) binding of intron sequences with the core; (ii) pairing of exon sequences with the internal guide sequence; and (iii) binding of the terminal guanosine to an unknown site within the core.     

Pseudo-cyclic oligonucleotides: in vitro and in vivo properties

We have designed and studied antisense oligodeoxynucleotides (oligonucleotides; oligos) which we call ‘pseudo-cyclic oligonucleotides’ (PCOs). PCOs contain two oligonucleotide segments attached through their 3′-3′- or 5′-5′-ends. One of the segments of the PCO is an antisense oligo complementary to a target mRNA, and the other is a short protective oligo that is 5–8 nucleotides long and complementary to the 3′- or 5′-end of the antisense oligo. As a result of complementarity between the antisense and protective oligo segments, PCOs form intramolecular pseudo-cyclic structures in the absence of the target RNA. The antisense oligo segment of PCOs used for the studies described here is complementary to an 18-nucleotide-long site on the mRNA of the protein kinase A regulatory subunit RI (PKA-RI). Thermal melting studies of PCOs in the absence and presence of the complementary RNA suggest that the pseudo-cyclic structures formed in the absence of the target RNA dissociate, bind to the target RNA, and form heteroduplexes. The results of RNase H cleavage assays suggest that PCOs bind to complementary RNA and activate RNase H in a manner similar to that of an 18-mer conventional antisense PS-oligo. In snake venom (a 3′-exonuclease) or spleen (a 5′-exonuclease) phosphodiesterase digestion studies, PCOs are more stable than conventional antisense oligos because of the presence of 3′-3′- or 5′-5′-linkages and the formation of intramolecular pseudo-cyclic structures. PCOs with a phosphorothioate antisense oligo segment inhibited cell growth of MDA-MB-468 and GEO cancer cell lines similar to that of the conventional antisense PS-oligo, suggesting efficient cellular uptake and target binding. The nuclease stability studies in mice suggest that PCOs have higher in vivo stability than antisense PS-oligos. The studies in mice showed similar pharmacokinetic and tissue distribution profiles for PCOs to those of antisense PS-oligos in general, but rapid elimination from selected tissues.     

Detection of an abasic site in RNA with stem-loop DNA beacons: application to an activity assay for Ricin Toxin A-Chain

The catalytic ability of Ricin Toxin A-Chain (RTA) to create an abasic site in a 14-mer stem-tetraloop RNA is exploited for its detection. RTA catalyzes the hydrolysis of the N-glycosidic bond of a specific adenosine in the GAGA tetraloop of stem-loop RNA. Thus, a 14-mer stem-loop RNA substrate containing an intact “GAGA” sequence can be discriminated from the product containing an abasic “GabGA” sequence by hybridization with a 14-mer DNA stem-loop probe sequence and following the fluorescent response of the heteroduplexes. Three DNA beacon probe designs are described. Beacon 1 probe is a stem-loop structure and has a fluorophore and a quencher covalently linked to the 5′- and 3′-ends. In this format the probe–substrate heteroduplex gives a fluorescent signal while the probe–product one remains quenched. Beacon 2 is a modified version of 1 and incorporates a pyrene deoxynucleoside for recognition of the abasic site. In this format both the substrate and product heteroduplexes give a fluorescent response. Beacon 3 utilizes a design where the fluorophore is on the substrate RNA sequence at its 5′-end while the quencher is on the probe DNA sequence at its 3′-end. In this format the fluorescence of the substrate–probe heteroduplex is quenched while that of the product–probe one is enhanced. The lower limit of detection with beacons is 14 ng/mL of RTA.     

Structure, organization and expression of the eukaryotic translation initiation factor 5, eIF-5, gene in Zea mays

The maize genomic DNA sequence encoding the eukaryotic translation initiation factor 5 (eIF-5) has been isolated from genomic library of maize seedlings and the exon–intron structure determined (accession number AJ132240). The length of genomic DNA sequenced was about 7 kb and contained two exons with the translation start site in exon 2. The only intron is located in the non-coding 5′ region and it is 1298 bp long with the splice acceptor and donor sites conforming to the AG/GT rules. Repetitive sequence fragments are located in the 5′ and 3′ intergenic region. The accumulation of eIF-5 mRNA was studied by RNA blot and in situ hybridization. The observed distribution of mRNA may correlate with the function of the protein, as it appears to be highly abundant in tissues where the proportion of cells actively dividing is very high, such as meristematic regions.     

HIV-2 genomic RNA contains a novel type of IRES located downstream of its initiation codon

Eukaryotic translation initiation begins with assembly of a 48S ribosomal complex at the 5' cap structure or at an internal ribosomal entry segment (IRES). In both cases, ribosomal positioning at the AUG codon requires a 5' untranslated region upstream from the initiation site. Here, we report that translation of the genomic RNA of human immunodeficiency virus type 2 takes place by attachment of the 48S ribosomal preinitiation complex to the coding region, with no need for an upstream 5' untranslated RNA sequence. This unusual mechanism is mediated by an RNA sequence that has features of an IRES with the unique ability to recruit ribosomes upstream from its core domain. A combination of translation assays and structural studies reveal that sequences located 50 nucleotides downstream of the AUG codon are crucial for IRES activity.     

Biologically active oligodeoxyribonucleotides-IX. Synthesis and anti-HIV-1 activity of hexadeoxyribonucleotides, TGGGAG, bearing 3′- and 5′-end-modification

We have determined that hexadeoxyribonucleotides (5′TGGGAG3′), with modified aromatic groups such as a trityl group at the 5′-end, have anti-HIV-1 activity in vitro. The 6-mer bearing a 3,4-dibenzyloxybenzyl (3,4-DBB) group at the 5′-end had the most potent activity and the least cytotoxicity. When the 3′-end of the 5′-(3,4-DBB)-modified 6-mer was substituted with a 2-hydroxyethylphosphate, a 2-hydroxyethylthiophosphate, or a methylphosphate group at the 3′-end, anti-HIV-1 activity increased. Moreover, among various 3′- and 5′-end-modified 6-mers that were tested, the 6-mer (R-95288) bearing a 3,4-DBB group at the 5′-end and a 2-hydroxyethylphosphate group at the 3′-end was the most stable, when incubated with mouse, rat, or human plasma. Therefore, R-95288 was chosen as the best candidate for possible use in therapy on the basis of its anti-HIV-1 activity.     

Molecular Biology and Cell-free Synthesis of Poliovirus

Abstract. Poliovirus is a small icosahedral particle consisting of only five species of macromolecules: 60 copies each of the capsid protein VP1-4; and one copy of single-stranded RNA, approximately 7500 nt long. The genome, linked at the 5′ end to a small protein VPg and 3′ polyadenylylated, is of plus strand polarity. After receptor-mediated uptake of the virus and release of the RNA into the cytoplasm, the genome serves as mRNA, encoding only a single polypeptide, the polyprotein. The polyprotein is cleaved co-translationally into numerous polypeptides by its own, internal proteinases 2A^pro, 3C^pro and 3CD^pro. Initiation of translation is mediated by a novel genetic element, called internal ribosomal entry site (IRES). IRES elements, which are 400 nt long RNA segments located within the 5′ non-translated region of the viral genome, are common to all picornaviruses. Their function renders translation of picornavirus mRNAs cap- and 5′-independent, an observation that has upset the dogma of cap-dependent translation in eukaryotic cells. IRES elements have also been used to genetically dissect the viral genome and to construct novel expression vectors. Genome replication is not fully understood, the major conundrum being the initiation of RNA synthesis by the primer-dependent viral RNA polymerase 3D^pol, a process leading to VPg-linked RNA products. Nearly all non-structural proteins appear to be involved in initiation, the proteinases 2A^pro and 3CD^pro included. A HeLa cell-free system has been developed that, on programming with plasmid-transcribed viral RNA, will perform viral translation, protein processing, RNA replication, and assembly of capsid protein and newly made genomic RNA. The final yield is infectious poliovirus. This result has nullified the dictum that no virus can replicate in a cell-free medium.     

On the discovery of interferon-inducible, double-stranded RNA activated enzymes: the 2'-5'oligoadenylate synthetases and the protein kinase PKR

The demonstration that double-stranded (ds) RNA inhibits protein synthesis in cell-free systems prepared from interferon-treated cells, lead to the discovery of the two interferon-induced, dsRNA-dependent enzymes: the serine/threonine protein kinase that is referred to as PKR and the 2′,5′-oligoadenylate synthetase (2′,5′-OAS), which converts ATP to 2′,5′-linked oligoadenylates with the unusual 2′-5′ instead of 3′-5′ phosphodiesterase bond. We raised monoclonal and polyclonal antibodies against human PKR and the two larger forms of the 2′,5′-OAS. Such specific antibodies proved to be indispensable for the detailed characterization of these enzyme and the cloning of cDNAs corresponding to the human PKR and the 69–71 and 100 kDa forms of the 2′,5′-OAS. When activated by dsRNA, PKR becomes autophosphorylated and catalyzes phosphorylation of the protein synthesis initiation factor eIF2, whereas the 2′-5′OAS forms 2′,5′-oligoadenylates that activate the latent endoribonuclease, the RNAse L. By inhibiting initiation of protein synthesis or by degrading RNA, these enzymes play key roles in two independent pathways that regulate overall protein synthesis and the mechanism of the antiviral action of interferon. In addition, these enzymes are now shown to regulate other cellular events, such as gene induction, normal control of cell growth, differentiation and apoptosis.     

Cation-dependent folding of 3′ cap-independent translation elements facilitates interaction of a 17-nucleotide conserved sequence with eIF4G

The 3′-untranslated regions of many plant viral RNAs contain cap-independent translation elements (CITEs) that drive translation initiation at the 5′-end of the mRNA. The barley yellow dwarf virus-like CITE (BTE) stimulates translation by binding the eIF4G subunit of translation initiation factor eIF4F with high affinity. To understand this interaction, we characterized the dynamic structural properties of the BTE, mapped the eIF4G-binding sites on the BTE and identified a region of eIF4G that is crucial for BTE binding. BTE folding involves cooperative uptake of magnesium ions and is driven primarily by charge neutralization. Footprinting experiments revealed that functional eIF4G fragments protect the highly conserved stem–loop I and a downstream bulge. The BTE forms a functional structure in the absence of protein, and the loop that base pairs the 5′-untranslated region (5′-UTR) remains solvent-accessible at high eIF4G concentrations. The region in eIF4G between the eIF4E-binding site and the MIF4G region is required for BTE binding and translation. The data support the model in which the eIF4F complex binds directly to the BTE which base pairs simultaneously to the 5′-UTR, allowing eIF4F to recruit the 40S ribosomal subunit to the 5′-end.     

Dual initiation sites of protein synthesis on foot-and-mouth disease virus RNA are selected following internal entry and scanning of ribosomes in vivo.

The initiation of protein synthesis on foot-and-mouth disease virus RNA occurs at two sites separated by 84 nucleotides. Immediately upstream from the first of these sites is the internal ribosome entry site (IRES), which directs the translation of this RNA to be cap-independent. The utilization of these two initiation sites has been examined using artificial fusion genes in vivo under a variety of conditions. Additional in-frame AUG codons have been introduced between these two authentic start sites to determine the mechanism by which ribosomes recognize the second start site. The results indicate that following internal entry of ribosomes on the 5' side of the first initiation codon, many fail to initiate protein synthesis at this position and scan along the RNA to the second initiation site. In the presence or absence of the IRES both initiation sites are efficiently used but the utilization of the two sites is slightly biased towards the second initiation site by the IRES. Furthermore, in the presence of the IRES, protein synthesis initiates at both sites independently of the activity of the cap-binding complex.     

The genome-linked protein VPg of the Norwalk virus binds eIF3, suggesting its role in translation initiation complex recruitment

The positive-strand RNA genomes of caliciviruses are not capped, but are instead covalently linked at their 5' ends to a viral protein called VPg. The lack of a cap structure typical of eukaryotic mRNA and absence of an internal ribosomal entry site suggest that VPg may function in translation initiation on calicivirus RNA. This hypothesis was tested by analyzing binding of Norwalk virus VPg to translation initiation factors. The eIF3d subunit of eIF3 was identified as a binding partner of VPg by yeast two-hybrid analysis. VPg bound to purified mammalian eIF3 and to eIF3 in mammalian cell lysates. To test the effects of the VPg- eIF3 interaction on translation, VPg was added to cell-free translation reactions programmed with either capped reporter RNA, an RNA containing an EMCV internal ribosomal entry site (IRES) or an RNA with a cricket paralysis virus IRES. VPg inhibited translation of all reporter RNAs in a dose-dependent manner. Together, the data suggest that VPg may play a role in initiating translation on calicivirus RNA through unique protein-protein interactions with the translation machinery.     

A single internal ribosome entry site containing a G quartet RNA structure drives fibroblast growth factor 2 gene expression at four alternative translation initiation codons

The 484-nucleotide (nt) alternatively translated region (ATR) of the human fibroblast growth factor 2 (FGF-2) mRNA contains four CUG and one AUG translation initiation codons. Although the 5'-end proximal CUG codon is initiated by a cap-dependent translation process, the other four initiation codons are initiated by a mechanism of internal entry of ribosomes. We undertook here a detailed analysis of the cis-acting elements defining the FGF-2 internal ribosome entry site (IRES). A thorough deletion analysis study within the 5'-ATR led us to define a 176-nt region as being necessary and sufficient for IRES function at four codons present in a downstream 308-nt RNA segment. Unexpectedly, a single IRES module is therefore responsible for translation initiation at four distantly localized codons. The determination of the FGF-2 5'-ATR RNA secondary structure by enzymatic and chemical probing experiments showed that the FGF-2 IRES contained two stem-loop regions and a G quartet motif that constitute novel structural determinants of IRES function.     

Stability of a stem-loop involving the initiator AUG controls the efficiency of internal initiation of translation on hepatitis C virus RNA.

The initiation of translation on the positive-sense RNA genome of hepatitis C virus (HCV) is directed by an internal ribosomal entry site (IRES) that occupies most of the 341-nt 5' nontranslated RNA (5'NTR). Previous studies indicate that this IRES differs from picornaviral IRESs in that its activity is dependent upon RNA sequence downstream of the initiator AUG. Here, we demonstrate that the initiator AUG of HCV is located within a stem-loop (stem-loop IV) involving nt -12 to +12 (with reference to the AUG). This structure is conserved among HCV strains, and is present in the 5'NTR of the phylogenetically distant GB virus B. Mutant, nearly genome-length RNAs containing nucleotide substitutions predicted to enhance the stability of stem-loop IV were generally deficient in cap-independent translation both in vitro and in vivo. Additional mutations that destabilize the stem-loop restored translation to normal. Thus, the stability of the stem-loop is strongly but inversely correlated with the efficiency of internal initiation of translation. In contrast, mutations that stabilize this stem-loop had comparatively little effect on translation of 5' truncated RNAs by scanning ribosomes, suggesting that internal initiation of translation follows binding of the 40S ribosome directly at the site of stem-loop IV. Because stem-loop IV is not required for internal entry of ribosomes but is able to regulate this process, we speculate that it may be stabilized by interactions with a viral protein, providing a mechanism for feedback regulation of translation, which may be important for viral persistence.     

L-Myc protein synthesis is initiated by internal ribosome entry

An internal ribosome entry segment (IRES) has been identified in the 5' untranslated region (5' UTR) of two members of the myc family of proto-oncogenes, c-myc and N-myc. Hence, the synthesis of c-Myc and N-Myc polypeptides can involve the alternative mechanism of internal initiation. Here, we show that the 5' UTR of L-myc, another myc family member, also contains an IRES. Previous studies have shown that the translation of mRNAs containing the c-myc and N-myc IRESs can involve both cap-dependent initiation and internal initiation. In contrast, the data presented here suggest that internal initiation can account for all of the translation initiation that occurs on an mRNA with the L-myc IRES in its 5' UTR. Like many other cellular IRESs, the L-myc IRES appears to be modular in nature and the entire 5' UTR is required for maximum IRES efficiency. The ribosome entry window within the L-myc IRES is located some distance upstream of the initiation codon, and thus, this IRES uses a "land and scan" mechanism to initiate translation. Finally, we have derived a secondary structural model for the IRES. The model confirms that the L-myc IRES is highly structured and predicts that a pseudoknot may form near the 5' end of the mRNA.     

Internal initiation of polyuridylic acid translation in bacterial cell-free system

The task of the present work was to answer the question: is the free 5′-end needed for effective translation of a model polyribonucleotide template — polyuridylic acid — in a bacterial (E. coli) cell-free system? For this purpose, the template activities of the original polyuridylic acid with its free 5′-end and the polyuridylic acid with blocked 5′-end were compared in the bacterial cell-free translation system. To block the 5′-end, the cytidylic oligodeoxyribonucleotide with fluorescein residue at its 5′-end and uridylic oligoribonucleotide sequence at its 3′-end, schematically described as FAM(dC)₁₀(rU)₅₀, was covalently attached (ligated) to the 5′-end of the template polyuridylic acid. It was shown that the efficiency of polyphenylalanine synthesis on the 5′-blocked template and on the polyuridylic acid with free 5′-end was virtually the same. It was concluded that bacterial ribosomes are capable of effectively initiating translation at the polyuridylic sequence independently of the 5′-end of template polyribonucleotide, i.e. via an internal initiation mechanism, in the absence of a Shine-Dalgarno sequence and AUG start codon.     

La autoantigen enhances translation of BiP mRNA

Translational initiation of the human BiP mRNA is directed by an internal ribosomal entry site (IRES) located in the 5′-untranslated region (5′-UTR). In order to understand the mechanism of the IRES-dependent translation of BiP mRNA, cellular proteins interacting with the BiP IRES were investigated. La autoantigen, which augments the translation of polioviral mRNA and hepatitis C viral mRNA, bound specifically to the second half of the 5′-UTR of the BiP IRES and enhanced translation of BiP mRNA in both in vitro and in vivo assays. This finding suggests that cellular and viral IRESs containing very different RNA sequences may share a common mechanism of translation.     

Internal initiation of translation of hepatitis C virus RNA: the ribosome entry site is at the authentic initiation codon.

Hepatitis C viral (HCV) RNA includes an internal ribosome entry segment (IRES) that extends some 30 nt into the coding region and promotes internal initiation of translation at the authentic initiation codon at nt 342. The 5'-boundary of this IRES was mapped by in vitro translation and transfection assays and was found to lie between nt 42 and 71. Within these IRES boundaries there are, in most HCV strains, three AUG triplets upstream of the authentic initiation site. Although the first, 5'-proximal, of these is absolutely conserved, a mutational analysis showed that it is not a functional initiation codon. In particular, the G residue could be substituted provided compensatory mutations were made to maintain base pairing. The other two upstream AUGs are not absolutely conserved, and mutation of the third (5'-distal) had little effect on IRES activity. When an additional AUG codon was introduced by single-site mutation just upstream of the authentic initiation codon, it was found to be used when most of the IRES had been deleted to generate an RNA translated by the scanning ribosome mechanism, but was not used in the background of the full-length IRES when internal initiation is operative. These results argue that the IRES promotes direct ribosome entry immediately at, or indeed very close to, the authentic initiation codon, and that the upstream AUGs do not serve as ribosome entry sites.     

Synthesis of oligo(5-aminopentanoic acid)-nucleobases (APN): potential antisense agents

Oligomers of 5-amino pentanoic acid nucleobases have been prepared for use as antisense agents. The synthesis of the 5′-end starter unit and the 3′-end monomer unit, as well as the coupling procedures used for oligomer formation are described.